Vacuum Soldering & Brazing

In the realm of metalwork, two techniques stand out for their precision and reliability: SOLDERING and BRAZING.

Both methods involve joining metal pieces without melting the base metals, utilizing a filler metal to bond the pieces together. While they share similarities, their distinct characteristics make them suitable for a variety of applications across industries.

Products for Soldering & Brazing Larger Volumes

Gloeioven - GLO

Metallic retort furnace
Up to 1000 °C in vacuum
Up to 400 L
pressure range 10^-6 mbar
Product Details

Stolp oven - V-L

Quartz retort furnace
Up to 1100 °C in vacuum
Up to 95 L
pressure range 10^-6 mbar
Product Details

Stolp oven - HBO

Metallic vacuum furnace
Up to 1600 °C in vacuum
Up to 60 L
pressure range 10^-6 mbar
Product Details

Smaller Volumes

Scharnierende Buisoven tot 1300°C - FST/FZS

Quartz or Ceramic tube
Up to 1300 °C in vacuum
Up to 10 L
pressure range 10^-5 mbar
Product Details

TF/TS 1200 / TF 1600°C

Quartz or Ceramic tube
Up to 1450 °C in vacuum
Up to 34 L
pressure range 10^-5 mbar
Product Details

Our Advantages for Soldering & Brazing

Precise temperature control of ± 0.5 K
Temperature uniformities better than ± 5 K
Best end vacuum and lowest leakage rates
CF type sealings instead of polymeric sealings at the relevant flanges
Double groove extraction of the door/hood flange to reduce the leakage rate
Special treatment of the inner surface to reduce the surface roughness, and therefore the surface coverage with mainly water. This results in a reduced pump down time in the high vacuum range
Mechanical decoupling of vibrations from the hot zone
Turbomolecular pumping system with automatic bypass function for evacuation down to the molecular range
Full data logging for full process control
Hydrogen or humidified hydrogen optionally available

Definitions

Soldering is a process that involves the use of a filler metal (solder) with a melting point below 450 °C. This technique is revered for its ability to create strong, electrically conductive joints, making it a cornerstone in the electronics industry. From circuit boards to wire connections, soldering is synonymous with precision and durability

Brazing, on the other hand, uses filler metals with a melting point above 450 °C but below the melting point of the base metals. The capillary action of the molten filler metal between close-fitting parts forms a strong and leak-proof bond. This method is widely utilized in the manufacturing of tools, automotive components, and various metal structures, offering robustness and resistance to high temperatures.

Insights

The chemical physical bonding between the materials can be metal-to-metal or insulator-to-metal. This connection must be robust, resistant to high temperatures, and compatible with vacuum conditions.

When subjected to vacuum or elevated temperatures, the presence of flux on an electronic component can lead to detrimental effects. The flux, which comprises acids and salts, transitions to a gaseous state due to its high vapor pressure. The subsequent condensation of flux material on insulators can create conductive pathways, resulting in leakage currents that may compromise the integrity of the costly component. Regrettably, the most active (and thus corrosive) fluxes tend to establish the most robust connections. Certain material attributes, such as vacuum resistance, are unattainable under standard atmospheric manufacturing conditions. Additionally, a notable issue with conventional atmospheres is the inevitable incorporation of gas impurities into the connection surface.

The resolution to this issue lies in employing high vacuum soldering and brazing techniques. In both methods, the bond between the two disparate materials is established through a third metallic substance, known as the solder or brazing filler material. The key difference between soldering and brazing is that soldering involves reversible adhesion, primarily, while brazing leads to the irreversible diffusion of the materials, resulting in a significantly stronger bond. The entire procedure is conducted in either a high-vacuum (HV) or an ultra-high vacuum (UHV) setting. Such environments eliminate the risk of oxidation and permit the use of flux-free solder materials.

Left: conventional connection with embedded gas impurities.
Right: connection established by high vacuum soldering and brazing with almost no impurities.

Vacuum & pump types

To meet the specific vacuum requirements of the customer for soldering & brazing, the leakage rate can be minimized to less than 10^-3 mbar·l/s and a high vacuum pumping system is attached. Given that heat transfer in a vacuum occurs solely through heat radiation, as described by Planck's radiation law, achieving optimal temperature uniformity within the hot zone is contingent upon a highly symmetrical design of the furnace. This design consideration is critical for ensuring even heat distribution and, consequently, the quality of the bonding process.

Membrane pump, Rotary vane pump

10 – 10^-2 mbar

Roots pump, Scroll pump

10^-2 – 10^-3 mbar

Turbo pump

10^-5 – 10^-6 mbar

Forced cooling mods

To meet the specific vacuum requirements of the customer for soldering & brazing, the leakage rate can be minimized to less than 10^-3 mbar·l/s and a high vacuum pumping system is attached. Given that heat transfer in a vacuum occurs solely through heat radiation, as described by Planck's radiation law, achieving optimal temperature uniformity within the hot zone is contingent upon a highly symmetrical design of the furnace. This design consideration is critical for ensuring even heat distribution and, consequently, the quality of the bonding process.

HBO

By circulating the gas through the retort incorporating a heat exchanger. The water cooled vessel accelerates cooling rates in cold wall vacuum furnaces.

V-L

Lifting the hood and blowing cold air over the quartz retort accelerates cooling and reduces cycle times.

GLO

By air cooling the retort from outside with side channel blower. This simple technique reduces cooling times by a factor of 4

Tube Furnace

Opening the furnace for a short time drops the temperature by natural air cooling. Optionally a fan can be used to speed up the cooling. But please be aware that the wear of insulation and heaters increases.

Post-Treatment & Analysis

Parts manufactured via Soldering & Brazing might be annealed in vacuum or gas atmosphere to ensure its stable connection. Stress within the connection between 2 materials will weaken its bonds and lower its quality and even lead to disruption.

QATM for example helps to ensure that a high quality of soldered and brazed parts are maintained. With their cutting, embedding, etching and phase analysis products QATM is the perfect partner for Materialography of parts manufactured with soldering & brazing techniques.

Visit QATM

Soldering & Brazing - FAQ

What is soldering & brazing?

Soldering and brazing are both metal joining processes utilising a filler metal to bond pieces together.

What is the difference between soldering & brazing?

The main difference between soldering and brazing is the temperature at which process is carried out. Soldering occurs at temperatures below 450 °C, while brazing occurs at temperatures above 450 °C. A vacuum environment ensures clean joints and minimal oxidation.

Vacuum brazing relies on its higher operating temperature to create strong, leak-proof joints between metal-to-metal and metal-to-ceramic (metal-to-insulator) components, making it ideal to join dissimilar material with different melting points.

Vacuum soldering by contrast operates on lower temperatures, making it ideal for delicate or heat sensitive metal-to-metal joints. This is a fast and cost-effective process that is well suited for mass production applications where precision and repeatability are key.

In which industries soldering & brazing is used?

Common soldering filler materials include Tin-Lead (Sn-Pb) alloys, such as 60:40 Tin-Lead which is widely used in electronics due to its near eutectic composition that leads to rapid solidification. High Tin-Lead (80:20 to 90:10) alloy compositions are often used for structural solders. Lead free alternatives for solder materials include Tin-Silver-Copper (Sn-Ag-Cu) ternary alloys.

For brazing applications, common filler materials used are Silver (Ag) alloys and Copper-Zinc (Cu:Zn) or also known as Brass alloys. These are used to join steels and are generally used to manufacture machinery components and structural parts. Depending on specific applications, other filler materials such as aluminium-silicon/zinc (Al:S/Zn) alloys or nickel-based alloys can also be utilised in manufacturing.

How does vacuum technology improve joint strength in soldering and brazing applications?

Vacuum soldering and brazing provides a controlled environment to achieve clean, stronger joints. Carbolite furnaces minimise oxidation, reducing contamination and trapped gases during the bonding process. The absence of oxygen prevents an oxide layer from forming leading to better wetting and enhanced joint strength.

Which industries use soldering and brazing?

Soldering and brazing are essential techniques applied across a range of industries. Carbolite furnaces are used in industries such as electronics, medical technology, aerospace and defence, precision engineering and many more.

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